Impurity scattering and quantum confinement in giant magnetoresistance systems

TL;DR

This paper uses ab initio calculations to analyze how impurity scattering and quantum confinement affect giant magnetoresistance in multilayer systems, revealing how impurity placement influences GMR behavior.

Contribution

It provides a detailed theoretical framework incorporating electronic structure and impurity effects to predict GMR variations in multilayers, aligning well with experimental data.

Findings

Impurity position significantly influences GMR magnitude.

Quantum confinement enables tailoring of GMR through impurity placement.

Different materials show distinct impurity effects on GMR.

Abstract

Ab initio calculations for the giant magnetoresistance (GMR) in Co/Cu, Fe/Cr, and Fe/Au multilayers are presented. The electronic structure of the multilayers and the scattering potentials of point defects therein are calculated self-consistently. Residual resistivities are obtained by solving the quasi-classical Boltzmann equation including the electronic structure of the layered system, the anisotropic scattering cross sections derived by a Green's function method and the vertex corrections. Furthermore, the influence of scattering centers at the interfaces and within the metallic layers is incorporated by averaging the scattering cross sections of different impurities at various sites. An excellent agreement of experimental and theoretical results concerning the general trend of GMR in Co/Cu systems depending on the type and the position of impurities is obtained. Due to the quantum confinement in magnetic multilayers GMR can be tailored as a function of the impurity position. In Co/Cu and Fe/Au systems impurities in the magnetic layer lead to high GMR values, whereas in Fe/Cr systems defects at the interfaces are most efficient to increase GMR.